0000000000882244

AUTHOR

Kenneth P. Sebens

showing 4 related works from this author

Mussels as a model system for integrative ecomechanics.

2015

Copyright © 2015 by Annual Reviews. All rights reserved. Mussels form dense aggregations that dominate temperate rocky shores, and they are key aquaculture species worldwide. Coastal environments are dynamic across a broad range of spatial and temporal scales, and their changing abiotic conditions affect mussel populations in a variety of ways, including altering their investments in structures, physiological processes, growth, and reproduction. Here, we describe four categories of ecomechanical models (biochemical, mechanical, energetic, and population) that we have developed to describe specific aspects of mussel biology, ranging from byssal attachment to energetics, population growth, an…

Settore BIO/07 - EcologiaRange (biology)Climate ChangeOceans and SeasPopulationMarine Biologymussel foot proteinsAquacultureBiologyOceanographytenacitybyssus dislodgment dynamic energy budget fitness mussel foot proteins tenacityRocky shoreTheoreticalAquacultureModelsPopulation growthAnimalsBody SizeeducationTemporal scalesEcosystemAbiotic componentPopulation Densityeducation.field_of_studyEcologybusiness.industryReproductionMusselModels TheoreticalbyssusfitnessMarine Biology & HydrobiologyBiomechanical PhenomenaBivalviaFisherydislodgmentdynamic energy budgetbusinessAnnual review of marine science
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Marine Animal Forests

2016

0106 biological sciencesGeographyEcology010604 marine biology & hydrobiology010603 evolutionary biology01 natural sciences
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Energetics, Particle Capture and Growth Dynamics of Benthic Suspension Feeders

2017

Marine benthic communities are dominated by suspension feeders, including those actively pumping water, passively encountering particles, or some combination of the two. The mechanisms by which particles are encountered and retained are now well known for a range of water flow conditions and organism morphologies. Recent research has attempted to quantify the energetic components of suspension feeding, including intake of particles, pumping rates, and metabolic costs of these activities. Energetic models depend strongly on environmental conditions, including temperature, flow speed, and food availability, for example. The effects of these variables have been combined for realistic scenarios…

0106 biological sciencesSettore BIO/07 - Ecologia010604 marine biology & hydrobiologyDynamics (mechanics)EnergeticsEnergetics Suspension feeding Benthos Particle capture Dynamic energy budgetBiology010603 evolutionary biology01 natural sciencesBenthic zoneChemical physicsSuspension (vehicle)Particle captureMarine engineering
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Estimation of fitness from energetics and life-history data: An example using mussels.

2017

Changing environments have the potential to alter the fitness of organisms through effects on components of fitness such as energy acquisition, metabolic cost, growth rate, survivorship, and reproductive output. Organisms, on the other hand, can alter aspects of their physiology and life histories through phenotypic plasticity as well as through genetic change in populations (selection). Researchers examining the effects of environmental variables frequently concentrate on individual components of fitness, although methods exist to combine these into a population level estimate of average fitness, as the per capita rate of population growth for a set of identical individuals with a particul…

0106 biological sciencesPhenotypic plasticityEcology010604 marine biology & hydrobiologyBiology010603 evolutionary biology01 natural sciencesSurvivorship curveStatisticsPer capitaPopulation growthProduction (economics)Set (psychology)Ecology Evolution Behavior and SystematicsSelection (genetic algorithm)OrganismNature and Landscape ConservationEcology and evolution
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